ANALYSIS OF MODIFICATIONS ON A SPARK IGNITION ENGINE FOR
OPERATION WITH NATURAL GAS
D. Ramasamy1,2, M.M. Noor1,3, K. Kadirgama1, M.M. Rahman1, W.G.B. Horizon2 1
Faculty of Mechanical Engineering, Universiti Malaysia Pahang, 26600 Pahang, Malaysia 2
Focus Applied Technologies, 6305 Highland PI, Black Forest CO 80908 USA. 3Department of Mechanical Engineering, University of Southern Queensland, Australia E-mail: deva@ump.edu.my / muhamad@ump.edu.my, contact: + 609 4246359
Abstract. Transportation is one of the key contributors to petroleum usage and emissions to the atmosphere.
According to researchers, there are many ways to use transport by using renewable energy sources. Of these solutions, the immediate solution which requires less modification to current engine technology is by using gaseous fuels. Natural gas is the fuel of choice for minor modification to current engines. As it can be derived from anaerobic digestion process, the potential as a renewable energy source is tremendous, especially for an agricultural country such a Malaysia. The aim in the future will be operating an engine with natural gas only with pipelines straight to houses for easy filling. The fuel is light and can be easily carried in vehicles when in compressed form. As such, Compressed Natural Gas (CNG) is currently used in bi-fuel engines, but is mostly not optimized in term of their performance. The focus of the paper is to optimize a model of natural gas engine by one dimensional flow modeling for operation with natural gas. The model is analyzed for performance and emission characteristics produced by a gasoline engine and later compared with natural gas. The average performance drop is about 15% from its gasoline counterpart. The 4% benchmark indicates that the modification to ignition timing and compression ratio does improve engine performance using natural gas as fuel.
1 Introduction
Future energy needs is demanding and the use of petroleum as one of the main source of energy is leading to fuel depletion in many countries in the world [1-3]. Malaysia being an oil producing country has slowly reducing reserves as shown in Figure 1 [4, 5]. Consequently, petroleum price in Malaysia increased in price due to high demand in the world market. As vast amount of petroleum is used in the transportation sector, many alternatives have been introduced for the past few decades to reduce petroleum consumptions as well as reducing emissions. Of these alternatives only natural gas in compressed form and liquefied petroleum gas (LPG) appear to be more economic for worthy implementation [6, 7]. Since LPG is totally derived totally from petroleum, natural gas is a better choice of fuel as it can be obtained from non-petroleum sources [8]. Natural gas is derived from biogenic (transformation of organic matter) and abiogenic (from earth crust) processes. The gas is abundant and world production prediction is reaching to 155.5 trillion cubic feet (tcf) from 106.6 tcf from year 2007 to year 2035[4].
The important of natural gas to the engine combustion was applied to several applications [9]. In Malaysia the natural gas production, consumption and exports shows
gradual production increase as compared to petroleum production. Figure 2 shows the current trend in natural gas usage in Malaysia [4]. Malaysia has the 8th largest reserves of natural gas with 83 tcf and producing 2.3 tcf as of year 2007. This ranking dropped in one year to 14th even though the reserve stood at 88 tcf [10]. More diversified methods are required for the gas production to be increased. The low demand of gas consumption compared to future production indicates the country is lacking gas fuelled technologies. However, more usage in vehicles is required to reduce the petroleum consumption.
Figure 1: Petroleum Production in Malaysia (Ghosh and Prelas 2009)
Figure 2: Malaysian Natural Gas Usage
To promote natural gas vehicles is a future target to reduce cost of operation of buses and cars. The country is an agricultural based country, planting crops such as oil palm, rubber, rice, mixed horticulture and coconut [11]. The waste products gathered from the plants is capable of producing natural gas from biogenic process. Biochemical methane potential (BMP), from crops and food using anaerobic digestion (AD) can reach up to 161-240 m3 CH4 /ton [12]. As Malaysia is producing 15000 tons of solid waste per day the amount of Methane generation will be around 3000000 m3. This source of methane is feasible to be used in vehicular usage. Research for gas powered vehicles is required to reduce dependency to petroleum. This can be very beneficial to future energy cost in the country. This paper outlines engine testing with natural gas for a common car engine in Malaysia. A one dimensional approach shows how much power and emission is generated by natural gas usage. The result is compared with a gasoline counterpart simulation to get a benchmark of power loss due to fuel exchange. A minor optimization to the engine’s compression ratio and ignition timing is done with natural gas so that the energy of the fuel is harnessed fully.
2 Engine Specification
The engine targeted for testing is a Perodua Myvi car engine named K3-VE, it has specification as in Table 1 below.
Table 1: Myvi Engine Specification
Engine Type 4-Stroke, EFI
Cylinders 4 inline Bore x Stroke (mm) 72.0 x 79.7 Displacement (cc) 1298 Compression Ratio 10:1 Max. Output (kW/rpm) 63/600 Maximum torque (Nm/rpm) 120/3200 Valve timing
Intake valve open BTDC, 30° to (–12)° Intake valve close ABDC, 10° to 52° Exhaust valve open BBDC, 30° Exhaust valve close ATDC, 2°
Table 2 shows the specification of the fuel that was used in the simulation. As natural gas has higher octane rating it has the capability to be compressed and ignite earlier. In doing this the higher energy content of the fuel is targeted to be fully optimized. 1-Dimensional engine simulation software, was used. The simulation software provides the guidelines to modify the engine. The simulation results will provide a strong example of how the engine behaves after modification. With the simulation results, decisions of which compression ratio and ignition timing map to be use can be made easily. The general setup of the software is shown in Figure 3 below.
Table 2 Fuel Spécifications (Heywood 1988, S. Maji 2000, Ramasamy, Aik Soon et al. 2013)
Fuel Gasoline CNG
Phase (25°C) Liquid Gas
Stoichiometric A/F Ratio 14.7 14.5 Energy Content, MJ/Kg 44 50 Composition Complex Hydrocarbon 92.73 % Methane Octane Rating 80-90 120
Flame Speed in air at stoichiometric, mm/s
390 375
Autoignition Temperature 480~550 ˚C 537 ˚C
3 Methodology
As discussed earlier in, the capabilities of the natural gas to be ignited earlier and compressed is tested out in the 1 dimensional simulation. Two criteria were identified for the simulation which are the ignition timing advancing for more fuel energy harvesting and compression ratio modification for increasing the fuel compression. The ignition timing of the engine has to be advanced to compensate the slow burn rate of the compressed natural gas. The ignition timing will be varied from 60° before top dead center (BTDC) to 30° after top dead center (ATDC). Engine power, torque, and combustion data will be taken with varying the ignition timing at fixed engine speed. With the simulation data, the ignition timing can be optimized for maximum brake power and torque.
DOI: 10.1051/
00031 (2016) matecconf/2016
MATEC Web of Conferences 7 ,4 7400031
The compression ratio was focus in this research. As compression ratio increase, the thermal efficiency of the engine will increase and this will increase the overall efficiency of the engine. This is shown in Figure 4. The octane number of compressed natural gas is 120. This allows the engine to run on higher compression ratio (Debnath, Sahoo et al. 2013). However higher compression ratio will induce knock to the engine. This can be simulated in the simulation software. The power curve and torque curve will be collected at different compression ratio (Korakianitis, Namasivayam et al. 2011). The compression ratio will be varied from 10 to 18. The knock plot will also be collected.
Figure 4: Thermal efficiency against different compression ratio
4 Results And Discussion
The result of the knock intensity at different compression ratio and ignition timing were presented. As compression ratio increases the knock intensity at low speed increases dramatically. This is due to the air fuel mixture has enough time to be influenced by the temperature of the combusted mixture. Similar result was found by [8, 18].Therefore at low speed the engine ignition timing needs to be advanced. Figure 5 to 8 shows the knock intensity at different engine speed and at different mass burn ratio of 50% crank angle.
Figure 5: Knock intensity at compression ratio 12 at various different mass burn ratio of 50% crank angle
Figure 6: Knock intensity at compression ratio 14 at various different mass burn ratio of 50% crank angle
Figure 7: Knock intensity at compression ratio 16 at various different mass burn ratio of 50% crank angle
Figure 8: Knock intensity at compression ratio 18 at various different mass burn ratio of 50% crank angle The power and torque curve at different compression ratio and ignition timing was discussed. Figure 9 to Figure 12 below shows the power and torque curve at different mass burn ratio of 50% crank angle. The effect of compression ratio to the power and torque curve diminishes as compression ratio increases (Caris and Nelson 1959, White, Steeper et al. 2006, Ramasamy, Zainal et al. 2014). Also, at low engine speed that is below 3000 rpm the ignition timing has to be advanced. However, above 3000 rpm the ignition timing needs to be retarded. The ignition timing is analyzed for 5 points from the baseline CNG. They are 10°CA BTDC, 2.5°CA BTDC, 5° CA ATDC, 12.5° CA ATDC and 20° CA ATDC. The negative denotes the piston position before TDC. Compression ratio 18 was ruled out due to the varying angle is too much, and it can compromise engine stability.
Thermal efficiency
Figure 9: Power and torque curve at compression ratio 12 at various different mass burn ratio of 50% crank angle
Figure 10: Power and torque curve at compression ratio 14 at various different mass burn ratio of 50% crank angle
Figure 11: Power and torque curve at compression ratio 16 at various different mass burn ratio of 50% crank angle
Figure 12: Power and torque curve at compression ratio 18 at various different mass burn ratio of 50% crank angle
Figure 13 shows the power and torque curve of gasoline and CNG without any modification. The average performance drop is about 19% from its gasoline counterpart (Anderson 2012, Vijayakumar, Ponnalagi et al. 2013, Ramasamy, Zainal et al. 2014). Figure 14 shows the power and torque curve of gasoline and CNG with compression ratio and ignition timing optimization achieved from the modification of compression ratio and ignition timing. The improvement can be compared by higher gradients in Figure 14 as compared to Figure 13. The optimized values shows improvement for the engine.
Figure 13: Power and torque curve of gasoline
and CNG without modification.
Figure14: Power and torque curve of gasoline
and CNG with optimization
5 CONCLUSION
Performance drop is about 15% from its gasoline counterpart. The 4% benchmark indicates that the modification to ignition timing and compression ratio does improve engine performance using natural gas as fuel. However, the modification of the engine using compression ratio and ignition timing can be further studied. The only way to increase the power of engine to its original gasoline specification is to apply forced induction system to the engine. A recommendation is that a turbocharged system with slightly lower compression ratio and optimized ignition timing will give the best efficiency.
ACKNOWLEDGEMENTS
The authors would like to express their deep gratitude to Universiti Malaysia Pahang (UMP) for provided the laboratory facilities and financial support under MOHE FRGS project no. RDU140125 and Automotive Excellence Centre (AEC).
DOI: 10.1051/
00031 (2016) matecconf/2016
MATEC Web of Conferences 7 ,4 7400031
References
1. Shafiee, S. and E. Topal, When will fossil fuel
reserves be diminished? Energy Policy, 2009.
37(1): p. 181-189.
2. Noor, M.M., A.P. Wandel, and T. Yusaf, Mild
combustion: the future for lean and clean combustion. International Review of Mechanical
Engineering, 2013. 8(1): p. 251-257.
3. Al-lwayzy, S. and T. Yusaf, Chlorella
protothecoides Microalgae as an Alternative Fuel for Tractor Diesel Engines. Energies, 2013.
6(2): p. 766-783.
4. Ghosh, T.K. and M.A. Prelas, NATURAL GAS. Vol. 1. 2009, Columbia: Springer Science + Business Media B.V. 281-381.
5. Supeni, E., et al., Experimental and modeling
investigation of the performance characteristics on diesel HCCI with hydrogen additive-a review. National Conference in Mechanical
Engineering Research, 2010. 2(1): p. 580-596. 6. Lapidus A.I, K.I.F.T.B.P., Natural Gas as Motor
Fuel. Chemistry and Technology of Fuels and
Oils, 2005. 41(3): p. 165-174.
7. Hosseini, S.E. and M.A. Wahid, Biogas
utilization: Experimental investigation on biogas flameless combustion in lab-scale furnace.
Energy Conversion and Management, 2013. 74: p. 426-432.
8. Yusaf, T., et al., Effect of Compress Natural Gas
Mixing on The Engine Performance and Emissions. International Journal of Automotive
and Mechanical Engineering, 2013. 8: p. 1438-1451.
9. Hairuddin, A.A., T. Yusaf, and A.P. Wandel, A
review of hydrogen and natural gas addition in diesel HCCI engines. Renewable and
Sustainable Energy Reviews, 2014. 32: p. 739-761.
10. Malaysian Gas, A., Malaysia : Natural Gas
Industry Annual Review 2012. 2013. p. 25-25.
11. Ahmad, F. Sustainable agriculture system in
Malaysia. in Regional Workshop on Integrated Plant Nutrition System (IPNS), Development in Rural Poverty Alleviation, United Nations Conference Complex, Bangkok, Thailand. 2001.
12. Yu, Z. and F.L. Schanbacher, Production of
methane biogas as fuel through anaerobic digestion, in Sustainable Biotechnology. 2010,
Springer. p. 105-127.
13. S. Maji, R.R.P.B.S., Comparison of Emmisions
and Fuel Consumption from CNG and Gasoline.
SAE Technical Paper, 2000(2000-01-1432). 14. Heywood, J.B., Internal Combustion Engine.
Vol. 21. 1988, New York: McGraw-Hill, Inc. 219-219.
15. Ramasamy, D., et al., Variation Of Airflow
Pattern Through Dissimilar Valve Lift In A Spark Ignition Engine. Journal of the Chinese
Institute of Engineers, 2013. 36(8): p. 1083-1096.
16. Debnath, B.K., N. Sahoo, and U.K. Saha,
Thermodynamic analysis of a variable compression ratio diesel engine running with palm oil methyl ester. Energy Conversion and
Management, 2013. 65: p. 147-154.
17. Korakianitis, T., A. Namasivayam, and R. Crookes, Natural-gas fueled spark-ignition (SI)
and compression-ignition (CI) engine performance and emissions. Progress in Energy
and Combustion Science, 2011. 37(1): p. 89-112.
18. Yusaf, T., G. Najafi, and D.R. Buttsworth,
Theoretical and experimental investigation of SI engine performance and exhaust emissions using ethanol-gasoline blended fuels, in 3rd International Conference on Energy and Environment (ICEE2009). 2009, IEEE Power
and Energy Society: Malacca, Malaysia.
19. Ramasamy, D., et al. Mass fraction burn
comparison of compressed natural gas and gasoline. in Applied Mechanics and Materials.
2014.
20. White, C., R. Steeper, and A. Lutz, The
hydrogen-fueled internal combustion engine: a technical review. International Journal of
Hydrogen Energy, 2006. 31(10): p. 1292-1305. 21. Caris, D. and E. Nelson, A new look at high
compression engines. 1959, SAE Technical
Paper.
22. Anderson, S.T., The demand for ethanol as a
gasoline substitute. Journal of Environmental
Economics and Management, 2012. 63(2): p. 151-168.
23. Vijayakumar, S., et al., Microwave assisted
synthesis of Co 3 O 4 nanoparticles for high-performance supercapacitors. Electrochimica